A Substrate Recognition Role for the [4Fe-4S]<sup>2+</sup> Cluster of the DNA Repair Glycosylase MutY

Porello, Silvia L.; Cannon, Michelle J.; David, Sheila S.

doi:10.1021/bi972433t

Cited by 103 publications

(104 citation statements)

References 38 publications

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“…However, the David laboratory has since performed several experiments to investigate the role of the cluster in this protein [36][37][38]. They have developed a method to remove reversibly the cluster from the protein and discovered that the cofactor is not necessary for protein folding nor does it contribute to the thermal stability of the protein.…”

Section: Introductionmentioning

confidence: 99%

DNA repair glycosylases with a [4Fe–4S] cluster: A redox cofactor for DNA-mediated charge transport?

Boal

Yavin

Barton

2007

Journal of Inorganic Biochemistry

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The [4Fe-4S] cluster is ubiquitous to a class of base excision repair enzymes, in organisms ranging from bacteria to man, and was first considered as a structural element, owing to its redox stability under physiological conditions. When studied bound to DNA, two of these repair proteins (MutY and Endonuclease III from Escherichia coli) display DNA-dependent reversible electron transfer with characteristics typical of high potential iron proteins. These results have inspired a reexamination of the role of the [4Fe-4S] cluster in this class of enzymes. Might the [4Fe-4S] cluster be used as a redox cofactor to search for damaged sites using DNA-mediated charge transport, a process well known to be highly sensitive to lesions and mismatched bases? Described here are experiments demonstrating the utility of DNA-mediated charge transport in characterizing these DNA-binding metalloproteins, as well as efforts to elucidate this new function for DNA as an electronic signaling medium among the proteins.

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Section: Introductionmentioning

confidence: 99%

DNA repair glycosylases with a [4Fe–4S] cluster: A redox cofactor for DNA-mediated charge transport?

Boal

Yavin

Barton

2007

Journal of Inorganic Biochemistry

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“…Several DNA repair proteins contain redox-active [4Fe-4S] clusters that are not required for folding (12,13). Examples of these proteins from the BER pathway, EndoIII, and MutY, are activated toward oxidation as they bind DNA (14)(15)(16). While EndoIII effectively removes oxidized pyrimidines, the repair protein is found in very low copy number in E. coli (approximately 500 copies per cell) (17,18).…”

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confidence: 99%

DNA charge transport as a first step in coordinating the detection of lesions by repair proteins

Sontz

Mui

Fuss

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

127

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Damaged bases in DNA are known to lead to errors in replication and transcription, compromising the integrity of the genome. We have proposed a model where repair proteins containing redoxactive [4Fe-4S] clusters utilize DNA charge transport (CT) as a first step in finding lesions. In this model, the population of sites to search is reduced by a localization of protein in the vicinity of lesions. Here, we examine this model using single-molecule atomic force microscopy (AFM). XPD, a 5′-3′ helicase involved in nucleotide excision repair, contains a [4Fe-4S] cluster and exhibits a DNAbound redox potential that is physiologically relevant. In AFM studies, we observe the redistribution of XPD onto kilobase DNA strands containing a single base mismatch, which is not a specific substrate for XPD but, like a lesion, inhibits CT. We further provide evidence for DNA-mediated signaling between XPD and Endonuclease III (EndoIII), a base excision repair glycosylase that also contains a [4Fe-4S] cluster. When XPD and EndoIII are mixed together, they coordinate in relocalizing onto the mismatched strand. However, when a CT-deficient mutant of either repair protein is combined with the CT-proficient repair partner, no relocalization occurs. These data not only indicate a general link between the ability of a repair protein to carry out DNA CT and its ability to redistribute onto DNA strands near lesions but also provide evidence for coordinated DNA CT between different repair proteins in their search for damage in the genome.DNA electron transfer | iron-sulfur clusters | oxidative damage

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“…The function, if any, for these clusters remains undetermined, although the FCL has been proposed as a structural element, aiding in DNA binding (9,30,38). Interestingly, however, MutY is capable of folding without the cluster; the [4Fe4S] 2ϩ cluster adds no stability to the enzyme, but it is critical for substrate binding and catalysis (39). The solvent-accessible [4Fe4S] 2ϩ cluster of Endo III undergoes decomposition with ferricyanide and is resistant to reduction, with an estimated midpoint potential of ϽϪ600 mV for the [4Fe4S] 2ϩ/1ϩ couple (2,38).…”

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confidence: 99%

DNA-mediated charge transport for DNA repair

Boon

Livingston

Chmiel

et al. 2003

Proc. Natl. Acad. Sci. U.S.A.

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223

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MutY, like many DNA base excision repair enzymes, contains a [4Fe4S] 2؉ cluster of undetermined function. Electrochemical studies of MutY bound to a DNA-modified gold electrode demonstrate that the [4Fe4S] cluster of MutY can be accessed in a DNA-mediated redox reaction. Although not detectable without DNA, the redox potential of DNA-bound MutY is Ϸ275 mV versus NHE, which is characteristic of HiPiP iron proteins. Binding to DNA is thus associated with a change in [4Fe4S] 3؉/2؉ potential, activating the cluster toward oxidation. Given that DNA charge transport chemistry is exquisitely sensitive to perturbations in base pair structure, such as mismatches, we propose that this redox process of MutY bound to DNA exploits DNA charge transport and provides a DNA signaling mechanism to scan for mismatches and lesions in vivo.D NA repair proteins that contain a FeS redox cofactor are ubiquitous (1-7), yet a role for these factors has been lacking. Two examples, highly homologous (8), are MutY (1) and endonuclease III (Endo III) (2, 9), base excision repair enzymes from Escherichia coli (10). MutY, containing 350 residues, acts as a glycosylase to remove adenine from G:A (11-13) and 7,8-dihydro-8-oxo-2-deoxyguanonsine:A mismatches (14-21); Endo III removes pyrimidines damaged by ring saturation, contraction, or fragmentation (22-29). Although MutY and Endo III have dramatically different substrate recognition features, they both contain a [4Fe4S] 2ϩ cluster (1, 2, 9) within a Cys-X 6 -Cys-X 2 -Cys-X 5 -Cys loop located near the protein C terminus (1, 9, 30). Based on sequence alignment, a loop defined by the first two ligating cysteines, called the FCL, is proposed to be a common element of DNA repair proteins (30), present throughout phylogeny (31-37). The function, if any, for these clusters remains undetermined, although the FCL has been proposed as a structural element, aiding in DNA binding (9,30,38). Interestingly, however, MutY is capable of folding without the cluster; the [4Fe4S] 2ϩ cluster adds no stability to the enzyme, but it is critical for substrate binding and catalysis (39). The solvent-accessible [4Fe4S] 2ϩ cluster of Endo III undergoes decomposition with ferricyanide and is resistant to reduction, with an estimated midpoint potential of ϽϪ600 mV for the [4Fe4S] 2ϩ/1ϩ couple (2, 38).Here, we consider whether the [4Fe4S] 2ϩ cluster in MutY can function in DNA-mediated charge transport (CT). Many laboratories have probed DNA-mediated CT chemistry (40-42). Using biochemical, spectroscopic, and electrochemical methods, we have shown that CT through DNA can proceed over long molecular distances in a reaction that is remarkably sensitive to intervening dynamical base pair structure (43-50). DNAmediated CT has been shown to yield oxidative DNA damage from a distance within nucleosome core particles (47) and HeLa cell nuclei (51). DNA binding proteins and peptides have also been shown to modulate and participate in long-range CT chemistry (48, 49), raising the question of the physiological relevance of DNA CT....

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A Substrate Recognition Role for the [4Fe-4S]²⁺ Cluster of the DNA Repair Glycosylase MutY

Cited by 103 publications

References 38 publications

DNA repair glycosylases with a [4Fe–4S] cluster: A redox cofactor for DNA-mediated charge transport?

DNA repair glycosylases with a [4Fe–4S] cluster: A redox cofactor for DNA-mediated charge transport?

DNA charge transport as a first step in coordinating the detection of lesions by repair proteins

DNA-mediated charge transport for DNA repair

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A Substrate Recognition Role for the [4Fe-4S]2+ Cluster of the DNA Repair Glycosylase MutY

Cited by 103 publications

References 38 publications

DNA repair glycosylases with a [4Fe–4S] cluster: A redox cofactor for DNA-mediated charge transport?

DNA repair glycosylases with a [4Fe–4S] cluster: A redox cofactor for DNA-mediated charge transport?

DNA charge transport as a first step in coordinating the detection of lesions by repair proteins

DNA-mediated charge transport for DNA repair

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A Substrate Recognition Role for the [4Fe-4S]²⁺ Cluster of the DNA Repair Glycosylase MutY